UTTARAKHAND TECHNICAL UNIVERSITY,

DEHRADUN

M TECH (Thermal Engineering)

Programme

2018

Examination

Duration (Hrs.)

Evaluation Scheme

Course

Code

Course Title Period

(Hrs.)

L T P Sessional University

Exam

Theory Practical CT Atten-

dance

TA Total ESE Total

1st Year 1st Semester MTET-100 Advanced

Mathematics

4 3 1 0 3 ……… 30 10 10 50 100 150

MTET-101 Advanced

Thermodynamics

4 3 1 0 3 ……… 30 10 10 50 100 150

MTET-102 Advanced Fluid

Mechanics

4 3 1 0 3 ……… 30 10 10 50 100 150

MTET-103 Advanced Heat

Transfer

4 3 1 0 3 ……… 30 10 10 50 100 150

MTET-11X Elective-I 4 3 1 0 3 ……… 30 10 10 50 100 150

Total 20 15 0 0 750

2nd Semester

MTET-201 Convective Heat &

Mass Transfer

4 3 1 0 3 ……… 30 10 10 50 100 150

MTET-22X Elective-II 4 3 1 0 3 ……… 30 10 10 50 100 150 MTET-22X Elective-III 4 3 1 0 3 ……… 30 10 10 50 100 150 MTET-22X Elective-IV 4 3 1 0 3 ……… 30 10 10 50 100 150 MTET-22X Elective-V 4 3 1 0 3 ……… 30 10 10 50 100 150

20 15 5 0 750

2nd Year 3rd semester MTES-301 Seminar 4 100 …. 100

MTEP-301 Project 4 100 100 200

MTED-301 M.Tech.

Dissertation

12 200 …. 200

Total 20 400 100 500

4th Semester

MTED-401 M. Tech.

Dissertation

24 250 250 500

Total 24 500

Semester wise distribution of Marks & Credit Points

Semester Credits

I 20

II 20

III 12

IV 12

Total 64

List of Elective Subjects for

M. Tech. (Thermal Engineering)

Subject code Subject Name

Elective-I

MTET-111 Solar Energy

MTET-112 Computational Fluid Dynamics & Heat Transfer

Elective-II to Elective-V

MTET-221 Power Plant Engineering

MTET-222 Refrigeration and air conditioning system design

MTET-223 I.C. Engines

MTET-224 I.C. Engines Combustion Process Modeling

MTET-225 Renewable Energy Systems

MTET-226 Gas turbine & Compressor

MTET-227 Cryogenic Systems

MTET-100 Advanced Mathematics L 3 T 1 P 0 Credit 04

Pre-requisite: Nil

Objective of Course: The course discusses exclusively the application of various topics useful

for thermal engineering course.

Details of Course

S.No Particulars Contact

Hours

1 Four standard forms of non-linear partial differential equations, linear equations

with constant coefficients.

04

2 Wave equation, Diffusion equation, Laplace equation in Cartesian, cylindrical

and spherical coordinates solution by separation of variables.

07

3 Matrix Theory, Solution of linear system of Algebraic and Differential Equation,

Eigen values and Eigen Vectors, Unitary , Hermitian and Normal Matrices.

04

4 Definition, linearity property of Z-Transform, Z-Transform of elementary

Functions, shifting theorems, initial and final value theorem, Convolution

Theorems, Inverse of Z-transform.

06

5 Fourier integral theorem, Fourier Transform, Application of Fourier Transform,

Laplace Transform and its applications.

06

6 Special Functions- Bessel’s, Legendres, Chebyshev Polynomials. 06

7 Calculus of variation : Euler’s Equation , solution of Euler’s

Equations,Geodesics, Isoperimetric Problems ,Several Dependent Variables,

Functionals involving Higher order Derivatives, Applications to Dynamical

Problems ,Weistress sufficiency Conditions for week and strong minimum and

maximum Extreme

09

Total 42

Suggested Books :

S.No Name of books/Authors/Publisher

1 “Partial Differential Equations”,I.N Snedon

2 “Engineering Mathematics” B.S Grewal, Khanna Publications

3 “Method of Applied Mathematics”, F.B Hilderbrand, PHI Publications

4 “Differential Equation & Calculus of variation”, L. Elsgeets, Mir Publications

Pre–requisite: Nil

Objective of Course: It is intended to give a thorough understanding of gas turbines,

compressors, gas turbine cycle, Energy and fluid flow Dynamics and power plant based

on gas turbine

Details of course:

S.No Particulars Contact

Hour

1 Introduction, development, classification and field of application of gas

turbines

3

2 Gas Turbines Cycles, Ideal and actual cycles, multi-stage compression:

reheating, regeneration, combined and cogeneration

6

3 Energy Transfer and Fluid Flow Characteristics

Energy transfer between fluid and rotor: axi-symmetric flow in compressor

and gas turbine

6

4 Centrifugal Compressor

Principles of operation; compressors losses; adiabatic efficiency; slip factor;

pressure coefficient; power unit; design consideration for impeller and

diffuser systems; performance characteristics.

6

5 Axial Flow Compressor

Elementary theory; vortex theory; degree of reaction; simple design;

elementary air foil theory; isolated air foil and cascade theory; three

dimensional flow; stages; stage efficiency and overall efficiency;

performance characteristics.

6

6 Turbines

Axial flow and radial flow turbines; impulse and reaction turbines;

fundamental relation and velocity triangles; elementary vortex theory;

limiting factors in turbine design application of airfoil theory to study of flow

through turbine blades; aerodynamic and thermodynamic design

considerations; blade material; blade attachments and blade cooling.

10

7 Gas Turbine Power Plant

Fuel and fuel feed system; combustion system-design and consideration and

flame stabilization; regenerator types and design; gas turbine power; plant

performance and matching; applications.

5

Total 42

MTET-226 Gas Turbine and Compressor L 3 T 1 P 2 Credit 04

Suggested book:

S.no Name of books/authors/publisher Years of

publishing

1. Gas turbine theory. Cohen and rogers, longmen

2. Theory and design of gas turbine and jet engines. Vincent, Mcgraw hills

3. Gas turbine principles and practice , cox newnes

4. Turbines, compressors and fans, yahya H.M, TMH 2002

5 Centrifugal compressors, boyce, M.P , Pennwell 2003

6 Gas turbine , ganeshan, V, THM 2002

Pre – requisite: Nil

Objective of Course: The course is intended to impart knowledge of solar energy with respect to its

Availability, utilization and economic viability

Details of Course:

S.No Particulars Contact

Hour

1 Introduction to solar energy 1

2 Fundamentals of solar radiations and heat transfer 8

3 Flat plate solar collectors 6

4 Focusing solar collectors 6

5 Solar thermal energy storage 4

6 Solar heating of buildings; active and passive methods 3

7 Solar refrigeration and air conditioning 2

8 Solar thermal power, solar desalination, solar drying of foods 3

9 Solar photovoltaic: analysis of other applications 4

10 Modeling of solar systems 3

11 Economic analysis 2

Total 42

Suggested Book:

S.no Name of books/authors/publisher Year of

publication

1 Solar engineering of thermal process, duffie and backman, john willey and inc. 1991

2 Principles of solar energy goswami kreith and kreider, taylor and francis 1997

3 Solar energy sukhatme, tata mcgraw hill, new delhi 1999

4 Solar energy garg and prakash, tata mcgraw hill, new delhi 2000

5 Solar energy tiwari, narosa publishing house 2002

6 Applied solar energy meinel, Addison wesiey 1997

MTET-111 Solar Energy L 3 T 1 P 0 Credit 04

Pre – requisite: Basic knowledge of refrigeration principles.

Objective of Course: To introduce the students to the field of low engineering (Cryogenics)

which has applications in Rocket propulsion, electronics, biological and medical science, food

preservation, mechanical designing etc.

Details of Course:

S.No. Particulars Contact

Hours

1 Introduction, Historical background, presents area involving cryogenics. 01

2 Low temperature properties of engineering materials: Mechanical properties,

Thermal properties, Electrical and Magnetic properties, Properties of cryogenics

fluids.

08

3 Gas liquification system: Joule Thomson effect, Adiabatic expension, simple

Linde-Hampson system, Precooled Linde-Hampson, Linde Dual pressure system,

Cascade system, claud system, Kapitza system, Collins Helium liquification

system,.

08

4 Critical component of liquification system: Effect of heat exchanger, effectiveness

on system performance, effect of compressor and expander efficiency on system

performance, effect of heat transfer to the system.

04

5 Cryogenic refrigeration system: Phillips refrigerators, importance of regenerator

effectiveness for Phillips refrigerator, Gifford-McMohan refrigerator.

04

6 Measurement system for low temperatures: Temperature measurement, flow rate

measurement, liquid level measurement.

04

7 Cryogenic storage and transfer system: cryogenic fluid storage vessels, insulations,

cryogenic transfer system.

06

8 Vacuum Technology importance of vacuum technology in cryogenics flow regime

in vacuum systems, conductance in vacuum systems. Calculation of pump down

time for a vacuum system.

08

Total 42

MTET-227 CRYOGENIC SYSTEM L 3 T 1 P 0 Credit 04

Suggested Books:

s.no Name of books/authors/publisher

1 Cryogenic system, barron, Mcgraw hill

2 Cryogenic system engineering timmerhaus and flyn, plenum press.

Pre-requisite: Course on I.C. Engine at U.G. level

Objective of Course: The course is intended to expose the students to the most widely used

mathematical models for in-cylinder spray and combustion process. These processes are most

important for fuel economy and pollutant emissions.

Details of Course:

S.No Particulars Contact

Hours

1 Essential features of combustion process in S.I. and C.I. Engines, Flame

Structure and speed, spray structure, auto ignition

4

2 Engine Combustion Modeling- An Overview 2

3 Modeling Fluid Motions in Engines, intake jet flow, swirl generation during

induction squish, prechamber flows, crevice flow and flow by

6

4 Modeling Flame Propagation and Heat Release in Engines, laminar burning

speed, flame propagation relations, heat release in diesel engines, zero

dimension burning rate function free gas jet theory, packet models

8

5 Knock, fundamentals, kinetic modeling of hydrocarbon combustion, auto

ignition, knock models

6

6 Modeling Spray, spray equation, droplet kinematics, spray atomization,

droplet breakup droplet/droplet and spray wall interactions, fuel

vaporization

8

7 Modeling pollutant formation in S.I. and C.I. engines, Models for NOx, CO

and soot formation

8

Total 42

MTET-224 I.C. Engine Combustion Process Modeling L 3 T 1 P 0 Credit 04

Suggested Books:

S.No Name of books/Authors/Publisher Year of

Publication

1 “Internal Combustion Engine Fundamentals”, H.Wood, McGraw Hill Inc. 1988

2 “Modeling Engine Spray and Combustion Processes”, G. Stiesch, Springer-

Verlag.

2003

3 “Combustion Modeling in Reciprocating Engines”, Eds: J.N. Mattavi, and

A. Charles, Plenum Press

1980

4 “Fluid Dynamics and Transfer of Droplets & Sprays”, W.A. Sirignano,

Cambridge University Press

2000

5 “Combustion: Physical and Chemical Fundamentals, Modeling and

simulation, Experiments, Pollutant Formation”, J. Warnatz, U. Mass,

R.W.Dirbble, Springer-Verlag.

2001

6 “I.C. Engines”, Ferguson, J Wiley 2004

Pre–requisite: Advanced Heat Transfer

Objective of course: The course discusses exclusively the various aspects of the convective heat

and mass transfer.

Details of Course:

S.No Particulars Contact

Hours

1 Introduction: Concepts and Conservation Principles and Laws 2

2 Equation of continuity, momentum, energy, mass and entropy,

Dimensional Analysis and Similarity Principles

5

3 Laminar Heat Transfer in Ducts 4

4 Laminar Boundary Layers 3

5 Turbulence fundamentals and models 3

6 Turbulence Boundary Layers 4

7 Natural Convection 4

8 Boiling 3

9 Condensation 3

10 Steady and Unsteady state molecular diffusion 2

11 Convective Mass Transfer 4

12 Simultaneous Heat and Mass Transfer 5

Total 42

MTET-201 Convective Heat & Mass Transfer L 3 T 1 P 0 Credit 04

Suggested Books:

S.No Name of Books/Authors/Publishers Year of

Publication

1 “Convective Heat Transfer”, V.S.Arpaci and P.S.Larsen, Prentice

Hall Inc.

1984

2 “Convective Heat Transfer”, L.C. Burmeister, John Wiley & Son

Inc.

1993

3 “Heat Transfer”, L.C.Thomas (Professional version 2nd edition),

Capstone Publishing.

4 “Convective Heat and Mass Transfer”, W.M. Kays, M.E. Crawfoed

and B. Weigand, Tata McGraw Hill, New Delhi.

2005

5 “Fundamentals of Momentum, Heat and Mass Transfer”, Editors:

James R. Welty, Charles E. Wicks, Robert E. Wilson, (4th edition),

John Wiley & Sons.

2001

Pre- requisite: Nil

Objective of course: the course discusses exclusively the various aspect of the internal

combustion engine.

Detail of course:

S.No. Particulate Contact

hour

1. Introduction and historical perspective 2

2. Thermodynamic analysis of I.C. engine cycle

Ideal models of engine process, thermodynamic relation for engine process,

cycle analysis, comparisons with real cycle

6

3. Combustion in spark ignition engine

Essential features of the process, thermodynamic analysis of SI engine

combustion, burned and unburned mixture states, analysis of cylinder data,

combustion process characterization, flame structure and speed, cyclic

variation in combustion, knock and surface ignition, fuel factors

10

4. Combustion in compression ignition engine

Essential features of the process, types of diesel combustion system,

phenomenological model of CI engine combustion, analysis of cylinder

pressure data, fuel spray behavior, spray structure, droplet size distribution,

spray evaporation, ignition delay

10

5. Pollutant Formation and Control

Pollutant formation in SI engines, nature and extent of the problem, nitrogen

oxides, carbon monoxide, unburned hydrocarbon emissions, catalytic

converters, pollutant formation in CI engines, oxides of nitrogen, carbon

monoxides and unburned hydrocarbon emission from diesel engines,

particulates, particulate traps, noise from diesel engines.

14

MTET-223 I.C. ENGINE L 3 T 1 P 0 Credit 04

Suggested Books:

S.No. Name of books/authors/Publisher Year of

Publication

1. “Internal Combustion Engine”, Heywood, J.B., McGraw Hill 1998

2. “Engineering Fundamentals of Internal Combustion Engine”,

Pulkrabek, W.W., Pearson

2005

3. “Introduction to Internal Combustion Engines”, Stone, R.

4. “Internal Combustion Engine in Theory and Practice”,Taylor, C.F.

5. “Internal Combustion Engines”, Ferguson, C.R., Kirkpatrick

6. SAE Transactions

7. “I.C. Engines”, Ferguson, J.Wiley 2004

Pre-requisite: Nil

Objective of course: Technological development depends upon primarily on energy. The

depletion of the conventional energy source and environmental problem associated with them

necessitate mankind to look for renewable energy system. This course expose the students and

society to the renewable energy system and thus will help in sustaining the development of the

society.

S.No. Particulars Contact

Hour

1 General-

Energy and Development, Energy demand and availability, energy crisis,

conventional and non-conventional, renewable and non-renewable energy

resources ,environmental impact of conventional energy usage; basic concept

of heat and fluid flow useful for energy systems.

6

2 Solar Energy Systems

Solar radiation data, solar energy collection, storage and utilization, solar

water heating, power generation, refrigeration and air conditioning, solar

energy system economics.

16

3 Micro and Small Hydro Energy System-

Resources assessment of micro and small hydro power, micro, mini and

small hydro power systems, economics, pump as turbine, special engines for

low heads, velocity head turbines hydrams, water mills, tidal power

4

4 Biomass energy Systems-Availability of biomass-agro, forest, animal,

municipal and other residues, bio conversion technologies, cooking fuels, bio

gas, producer gas, power alcohol from biomass, power generation, internal

engine modifications, and performance, system economics

4

5 Wind energy system- Wind data, horizontal and vertical axis wind mills, wind

farms, performance and economics of wind energy

4

6 Integrated Energy System- Concept of integration of conventional and non-

conventional energy resources and systems, integrated energy system design

5

MTET-225 Renewable L 3 T 1 P 0 Credit 04

and economics

Total 40

Suggested Books:

S.No Name of Books/Author/Publisher

1 “Solar Engineering of Thermal Process”, Duffie & Beckman,John Wiley

2 “Energy, The Biomass Option’, Bungay, John Wiely

3 “Introduction to Wind Energy”,Lysen ,Georgia Inst.

4 “Energy”, Doolittle, MTrix Pub.

5 “Energy and environmental’,Folwer,Mcgraw Hill

6 “Solar Energy”, S.P. Sukhatme, Tata Mcgraw Hill

7 Energy hand book,Loftness

Pre-requisite: U.G. level course in fluid mechanics

Objective of course: The course is design to provide advanced analytical tool for fluid flow

analysis.

S.No. Particulars Contact

hour

1 Review of basic concept, concept of continuum, type of fluids, tensor

analysis.

03

2 Basic laws in integral form, Reynold’s transport theorem, mass,

momentum, and energy equations in integral form and their applications.

05

3 Differential fluid flow analysis, continuity equation, Navier Stroke’s

equations, and excat solutions, energy equations.

07

4 Ideal fluid flow analysis, two dimensional flow in rectangular and polar

co-ordinates; continuity equation and the stream function; irrotationality

and the velocity potential function, vorticity and circulation, plane

potential flow and complex potential function. Sources, sinks, doublets and

vortices, flow over bodies and D-Alembert’s paradox; aero foil theory and

its application.

08

5 Low Reynold’s number flow, approximation, of N-S equation,approximate

solution of Navier Stroke’s equation, Stoke’s and Oseen flows,

hydrodynamics theory of lubrication.

04

6 Large Reynold’s number flow, approximation, Prandtl’s boundary layer

equations, Blausius solutions. Falkner-Skan solutions, momentum integral

equation. Halstein and Bohlen method, thermal boundary layers.

08

7 Compressible fluid flow, One dimensional isentropic flow, Fanno and

Rayleigh flows, chocking phenomenon, normal and oblique shocks.

07

total 43

MTET-215 Advanced Fluid Mechanics L 3 T 1 P 0 Credit 04

Suggested Book:

S.No. Name of Books/ Authors/Publisher Year of Publication

1 Foundation of fluid mechanics, S.W. Yuan, Prentice Hall inc 1998

2 Advanced engineering fluid mechanics, K. Murlidhar and

G. Bishwas, Narosa Publication

1996

3 Compressible flow, P.H. Oosthuizen and W. E. Carscallen,

Mcgraw Hills inc.

1997

4 Introduction to fluid dynamics, G. K. Balchlor, Cambridge

University Press.

2000

5 Viscous fluid flow F. M. White, Mcgraw inc. 2005

6 Boundary layer theory H. Schlichting, K. Gersten, E. Krause,

H. J. Oertel, C. Mayes (8th edition) Sringer verlag

2004

MTET-103 Advanced heat transfer L 3 T 1 P 0 Credit 04

Pre-requisite: U.G. level course in heat transfer.

Objective of course: The course is design to provide advanced analytical tool for heat transfer

analysis.

S. No. Contents Contact

Hours

1. Heat Conduction: Fourier’s law, thermal conductivity of matter, heat

diffusion equation for isotropic and anisotropic media, boundary and initial

conditions; One-dimensional steady-state conduction through plane wall,

cylinder and sphere, conduction with thermal energy generation, heat

transfer from extended surfaces, radial fins and fin optimization; Transient

conduction – lumped capacitance method and its validity, plane wall and

radial systems with convection, semi-infinite solid.

12

2. Heat Convection: Boundary layers concepts, laminar and turbulent flows,

conservation equation, non-dimensional analysis, boundary layer equations,

Reynolds analogy for turbulent flows; Forced convection inside tubes and

ducts – correlations for laminar and turbulent forces convection; Forced

convection over exterior surfaces – bluff bodies, packed beds, tube bundles

in cross flow; Natural convection; Combined free and forced convection;

Combined convection and radiation.

10

3. Heat Transfer with Phase Change: Nucleate, film and pool boiling, boiling

in forced convection; Filmwise and dropwise condensation

6

4. Thermal Radiation: Fundamental concepts, radiation intensity and its

relation to emission, irradiation and radiosity, blackbody radiation, surface

emission, surface absorption, reflection, and transmission, gray surface;

Radiation exchange between surfaces, view factor, blackbody radiation

exchange, radiation exchange between diffuse gray surfaces in an enclosure

with absorbing and emitting media; Flame Radiation, solar Radiation.

8

5. Numerical Methods in Heat Transfer: Finite difference method for 4

numerical simulation of steady state and transient heat transfer problems.

Total 40

MTET-222 Refrigeration and air conditioning

system and design

L 3 T 1 P 0 Credit 04

S. No. Contents Contact

Hours

1. Review of thermodynamic principles of refrigeration.Carnot

refrigeration cycle – Vapour compression refrigeration cycle – use of

P.H. charts – multistage and multiple

evaporator systems – cascade system – COP comparison. Air

Refrigeration cycles.

7

2. Compressors – reciprocating and rotary (elementary treatment), Types of

condensers, evaporators, cooling towers – Functional aspects.

Refrigerants – properties-selection of refrigerants, Alternate Refrigerants,

Cycling controls.

10

3. Psychrometric processes use of psychrometric charts – Grand and Room

Sensible Heat Factors – bypass factor – air washers, requirements of

comfort air conditioning, summer and Winter Air conditioning.

9

4. Cooling load calculation working principles of Centralized Air

conditioning systems, Split, Ductable split, Packaged Air conditioning,

VAV & VRV Systems. Duct Design by equal friction method, Indoor Air

quality concepts.

9

5. Vapor Absorption system Ejector jet, Steam jet refrigeration, thermo

electric refrigeration. APPLICATIONS: ice plant food storage plants

milk chilling plants.

7

Total 42

MTET-221 POWER PLANT ENGINEERING

1. A Review: Rankine Cycle with reheat & regeneration; binary vapor cycle, gas power

cycle and flow through nozzles.

2. Introduction: resources & development of power in India, hydro, thermal and nuclear

energy, present power position & future planning of policies in India.

3. Thermal power plant: Introduction, fossil fuels & its resources, Fuel properties &

storage, classification of coal, use of high ash coal, lignite coal, drying, storage and

handling of liquid fuels, types of petroleum fuels, producer gas, fuel firing , furnace

construction, grates , pulverizers, oil and gas burners & fluidized bed combustion system.

Ash handling and flue gas analysis. High pressure boiler, super critical boilers. Steam

plant accessories- economizers, air pre heaters, super heaters, soot blowers, condensers,

cooling towers, effect of component characteristics on the plant performance and variable

load problem.

4. Diesel electric power plants :

Field of use, outline of diesel power plant, different systems, super charging. Diesel;

power plant, efficiency, heat balance. Present trends in diesel power plant research.

5. Gas Turbine plants.

Introduction, classification & different types of gas turbine plants. Analysis of closed and

open cycle constant pressure gas turbine plants. Methods to improve the thermal

efficiency of as simple open cycle constant pressure gas turbine plant; auxillaries and

controls. Environment impacts of gas turbine power plants.

6. Hydro-electric power plant:

Hydrology-rain fall, run off & its measurement hydrograph & storage of water.

Classification of hydro units, design construction & operation of different components of

hydro electric power stations.

7. Nuclear power plants:

Basic principles of Nuclear Energy, classification and main part of nuclear research ,

different types of reactors i.e. PWR,BWR , heavy water reactors gas cooled reactors,

liquid metal cooled reactors. Organic moderated cooled reactors, breeder reactors plant

operations, safety features & radioactive waste disposal.

8. Economic analysis of power plants and tariffs:

Instrumentation and control in thermal power plants; energy conservation and

management.

9. Environment aspects of power generation:

Pollutants from fossils fuel and health hazards control of emissions and particulate

matter, desulfurization, coal gasification and introduction to green-house effect.

SUGGESTED BOOKS FOR POWER PLANT ENGINEERING

1. “Power plant theory and design”, Potter, Ronald Press

2. “Modern Power Station Practices”,CEGN, Pergamon Press

3. “Power Plants”, Zerban & Nye, International

4. “Nuclear Power Plant equipment”,Lish, Industrial Press

5. “A course In Power Plant Engineering”, Arora & Domkundwar, Dhanpatrai , New

delhi

6. “Power Plant engineering”, P.K. Nag, Tata McGraw Hills

MTET-101 Advance Thermodynamics

S.No. Particulars Contact hour

1 Review of I & ll laws of thermodynamics, transient flow

analysis, entropy balance, entropy generation.

05

2 Exergy Analysis, concepts, exergy balance, exergy transfer,

exergetic efficiency, exergy analysis of power and

refrigeration cycles.

09

3 Real gases and mistures, equations of state, thermodynamics

property relations, residual property functions, properties of

saturation states.

06

4 Thermodynamics properties of homogeneous mixtures,

partical molal properties, chemical potential, fugacity and

fugacity coefficient, fugacity relations for real gas mixtures,

ideal solutions, phase equilibrium, rault’s law.

08

5 Reacting systems, l & ll Law analysis of reacting system,

absolute entropy and the third law, fuel cells, chemical

energy, Exergectic efficiency of reacting systems, Chemical

equilibrium, equilibrium flame temperature.

14

Suggested Book:

Advance Thermodynamics for Engineers, K. Wark, John Willey & Sons

Advance Engineering Thermodynamics, A. Bejan, John Willey & Sons

Advance Engineering Thermodynamics, Annamalai & Puri, CRC Press

Fundamental of Engineering Thermodynamics, A. Bejan, G. Tsatsarones, & Moran, John Willey

& Sons

MTET-112Computational Fluid Dynamics and Heat Transfer

S.NO. Particulars Contact hour

1 Introduction; conservation equation, mass, momentum and

energy equation; convective form of the equation and general

description.

03

2 Clarification into various type of equation, parabolic, elliptic,

boundary and initial conditions; over view of numerical

methods.

04

3 Finite difference methods; different means for formulating

finite difference equation, Taylor series expansion, integration

over element, local function method; finite volume methods;

central, upwind and hybride formulations and comparison for

convection-diffusion problem; treatment of boundary

conditions; boundary layer treatment; variable property;

interface and free surface treatment; accuracy of f.d. method.

10

4 Solution of finite difference equations; iterative methods;

matrix inversion methods; ADI methods; operator splitting,

fast. Fourier transforms, applications.

07

5 Numerical grid generation; basic ideas; transformation and

mapping.

05

6 Finite element methods; Rayleigh- Ritz, Galerkine and least

square methods; interpolation functions; one and two

dimensional element; applications.

10

07 Phase change problems, different approaches for moving

boundary; variable time step method; enthalpy methods.

04